Direction and distance finder for locating distress signals

ABSTRACT

The present invention relates to a system and method for locating the direction and distance to a RF signal source from an avalanche beacon to find an avalanche victim. The system and method includes a RF signal locator and a graphical display residing on the signal locator. The receiver graphical display provides the searcher with an initial way point reading that includes directional and distance data associated with the beacon RF signal source from the avalanche beacon. The directional and distance data is based upon the received RF signals. A processor within the locator receiver receives and measures RF signals emitted by the RF signal source. The locator advantageously provides continuous subsequent way point readings for the user, where the subsequent way point readings include directional and distance data associated with the RF signal source. The distance data provided by the subsequent way point readings is based upon a path loss slope of the received RF signals from the avalanche beacon.

This is a continuation-in-part of U.S. application Ser. No. 10/709,656filed May 20, 2004 now U.S. Pat. No. 6,933,889 and of Provisional U.S.application Ser. No. 60/477,125 filed Jun. 9, 2003.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a direction and distance estimationsystem and method based upon characteristics of the Radio Frequency (RF)and the power path loss curve to locate victims.

2. Description of Related Art

Aircraft emergency locator systems such as ELTs (Emergency LocatorTransmitters) and terrestrial location systems such as PLBs (PersonalLocator Beacons) are well known in the existing art. Individuals lost atsea and fortunate enough to have emergency location identificationdevices such as an Emergency Position Indicating Radio Beacon (EPIRB),can send out RF signals with the hopes that their distress signals willbe picked up by maritime stations or satellites, which can in turn,relay the information to the proper authorities.

Handheld or mobile location devices and systems can effectively locatethe directional parameters associated with distress beacons; however, inorder to obtain accurate distance readings, one must employ the use ofsatellites and global positioning systems (GPS). If a distress beaconemits a GPS signal to orbiting satellites, then a searcher may easilylocate the distress beacon based upon the GPS reading. Many distressbeacons currently being used are not equipped to transmit GPS readingsand merely emit a RF signal for reception by a handheld, mobile,stationary or orbiting satellite receiver. As stated above, the RFreceivers used to track and locate a RF signal from a distress beaconeffectively locate the direction of the beacon, however reliabledistance readings under this application are not possible. The lack ofdistance readings to the beacon can unnecessarily prolong or possiblyimperil a search and rescue operation. If an individual is attempting tolocate a person lost at sea, then initial movement of a search vessel iscarefully monitored in order to prevent possibly running over thedistressed victim. If the search vessel is a great distance from thedistressed victim, then valuable time may be lost due to the necessityto move slowly during the searching process. If accurate distancereadings were available, then the searching process could be shortenedand therefore increase the likelihood of a successful rescue.

Directional and distance information may be equally important to searchand rescue operations on land. Searchers may need to locate a distressbeacon in dense woods or an urban metropolitan area. The beacon may beused by hikers, off road adventurers, skiers, campers and children. Ifthe searcher is limited to directional data only, then even theeffectiveness of a land search could be significantly diminished.

Avalanches are a great hazard to skiers, hikers and climbers and otherpeople in mountain regions during winter. If a person is buried by snow,there is a very short period of time available to recover the personbefore he or she suffocates or dies of exposure due to the snow pack.The time factor in locating someone buried in an avalanche is a criticalfactor in the survival of the person buried. Electronic locating devicesare known in the prior art to find victims of an avalanche that areburied under snow. Avalanche rescue devices manufactured by severalcompanies transmit an RF signal on a frequency of 457 kHz. U.S. Pat. No.6,031,482 issued to Lemaitre, et al., Feb. 29, 2000, discusses a methodand system for sensing and locating a person, e.g. under an avalanche.Various types of electronic systems are discussed in this patent. U.S.Pat. No. 6,167,249 issued to Hereford, et al. discloses an avalanchevictim locating transceiving apparatus that uses a plurality ofdifferent antennas that are arranged to provide directional and distanceestimates to the victim along the lines of flux. None of the referencesexploit the RF characteristics of the field or power path loss curve toestimate a point to point direction and distance to an avalanche victim.

It would therefore be advantageous to provide a method and system forthe location of a distress beacon that would provide the searcher withaccurate distance and direction estimations. By providing a searcherwith distance and directional estimations, the search time may bereduced significantly without endangering the distress victim. Although,the search and rescue operation has been discussed in association withsea and water rescue, distance estimations are also advantageous inregard to terrestrial search and rescue missions. It would also beadvantageous if a handheld device facilitated the operation of thepresent system and method.

SUMMARY OF THE INVENTION

The present invention provides a system and method for locating thesource of a RF signal. The present invention enables a user to locatethe source of a RF signal as emitted by a distress beacon during asearch and rescue operation. The present invention advantageously notonly provides directional data as to the direction of the RF signalsource, but also provides an estimated distance between a receiver andthe RF signal source. A receiver according to the present inventionadvantageously provides direction and distance estimates based uponsignal strength in a certain direction or over a certain distance.

In one exemplary embodiment of the present invention, a searcher using asignal locator (RF receiver) obtains the direction of the RF signalsource, i.e., the distress beacon. The direction may be ascertainedbased upon signal strength readings taken by the locator where thestrongest signal reading emits from the direction of the beacon. Afterobtaining the signal direction, the locator stores the initial RF signalstrength reading and provides an estimated distance reading. The initialdirectional data and distance data provide an initial way point reading.The user may then proceed in the indicated direction and the locatorproduces continuous subsequent way point readings. The subsequentdistance readings may be determined based upon the path loss slope ofthe received RF signals. As the distance between the receiver and beacondecreases, the path loss slope dramatically increases. The path lossslope is the x-y graph of the beacon signal power strength as a functionof distance from the receiver to the RF beacon. The present inventionadvantageously exploits this phenomenon in order to provide accurate andeffective distance estimations.

It is therefore an object of the present invention to provide a systemthat includes a signal locator where a graphical display resides on thesignal locator. The graphical display provides the user with an initialway point reading that includes directional and distance data associatedwith the RF signal source. The directional and distance data is basedupon the received RF signals. A processor within the locator receives,measures and stores RF peak signal strength of transmissions emitted bythe RF signal source. The locator advantageously provides continuoussubsequent way point readings for the user, where the subsequent waypoint readings include directional and distance data associated with theRF signal source. The distance data within the subsequent way pointreadings may be based upon a path loss slope of the received RF signals.

It is therefore another object of the present invention to provide amethod for locating a RF signal source using a signal locator comprisingthe steps of: initiating a search mode for the signal locator; obtaininga direction for the RF signal source based upon a RF signal readings;moving a certain distance with respect to the direction of the signaland obtaining an initial waypoint reading, where the initial way pointreading is based upon the rate of change of the RF signal strength asreceived by the signal locator; continuing to traverse with respect tothe initial way point reading; and continuously obtaining subsequent waypoint readings based upon subsequent directional readings and subsequentdistance readings, where the subsequent distance readings are based uponthe rate of change of the RF signal strength as received by the signallocator.

It is therefore another object of the present invention to provide amethod for locating a RF signal source using a signal locator comprisingthe steps of: initiating a search using the signal locator; maneuveringthe signal locator toward a plurality of compass directions in order toobtain a RF signal strength in the plurality of compass directions;obtaining a direction for the RF signal source based upon a RF signalstrength in the plurality of compass directions; providing an initialcompass reading toward the signal source; advancing the signal locatorin the direction of the initial compass reading; initiating a way pointreading, based on the directional readings and distance readings, wherethe distance readings are based upon the rate of change of the RF signalas received by the signal locator; continuing to advance the signallocator; initiating a subsequent way point reading, based on subsequentdirectional readings and subsequent distance readings, where thesubsequent distance readings are based upon the rate of change of the RFsignal as received by the signal locator; continuing to advance thesignal locator; and repeatedly initiating subsequent way point readingsuntil the RF signal source is located.

The present invention also provides a system and method for locating anavalanche victim. Many of the avalanche rescue systems that arecurrently being manufactured use an avalanche beacon that transmits anRF signal at 457 kHz (amplitude modulated) that is attached to theperson buried in the avalanche for location. Typically, the victim'stransmitter emits a dipole flux pattern (magnetic field pattern). Thepresent invention enables a searcher with a receiver built in accordancewith the present invention to locate the source of this transmittedfield as emitted by a distress beacon during a search and rescueoperation. The present invention not only provides point to pointdirectional data as to the direction of the RF field source based onflux field characteristics, but also provides an estimated distancebetween the searcher's receiver and the victim's transmitter fieldsource using path loss slope and/or triangulation. A receiver inaccordance with the present invention advantageously provides directionand distance estimates based upon field signal strength transmitted bythe victim's transmitter avalanche or field strength changes in acertain direction with regard to the flux lines and/or over a certaindistance.

In the event of an avalanche in which one or more persons are buried,each having an avalanche beacon transmitting at 457 kHz, a searcherusing a receiver in accordance with the present invention obtains theestimated direction and distance of the RF magnetic field source basedon transmissions from the victim's avalanche beacon. The direction maybe ascertained based upon field strength readings taken by the receiverof the searcher where the strongest field strength reading is orientedparallel to the induction line from the distress transmitter. Afterobtaining the direction of the induction lines, the searcher moves acertain distance (e.g., eight feet) in any direction while receivingmore signal strength data and flux line direction information enablingthe algorithm in the receiver to analyze the data, which includesgeometric calculations for direction (defined as triangulation mode foravalanche beacons) and direct the searcher in the best direction toobtain optimum data or towards the location of the distress beaconsource. The distance to the distress beacon source from the searcher iscalculated using the path loss slope mode (high rate of change of fieldstrength close to the transmitter and a decreasing slope the furtheraway from the transmitter one is). The signal strength may be also usedto determine distance if the radiated power of the victim's transmitteris known, which is commonly the case with avalanche beacons. Thesearcher may then proceed in the indicated direction where additionaldata and processing results in increased accuracy of the location of thedistress beacon (RF source). The path loss slope is the x-y graph of thebeacon signal power strength as a function of distance between thedistress beacon and the searcher's receiver location in the field. Thepresent invention provides a system that includes a receiver inaccordance with the invention that may also include a graphical displayto provide the searcher with an initial way point reading that includesdirection and estimated distance data associated with the magnetic fieldsource.

It is an object of this invention to provide an avalanche victim locatorthat includes estimates of direction and distance to the distress beaconof the person that is the victim of an avalanche.

In accordance with these and other objects which will become apparenthereinafter, the instant invention will now be described with particularreference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a symbolic exemplary overview of a locating systemaccording to the present invention.

FIG. 2 shows a top plan view of a locator (RF) receiver according to thepresent invention.

FIG. 3 shows a top plan view of the receiver shown in FIG. 2 includingan exemplary graphical display according to the present invention.

FIG. 4A shows a graph of RF signal strength path loss characteristics.

FIG. 4B shows a graph displaying exemplary slopes associated with a pathloss curve according to the present invention.

FIG. 5A shows a flow chart describing a preferred locating methodaccording to the present invention.

FIG. 5B shows a flow chart describing an alternate exemplary locatingmethod according to the present invention.

FIG. 6 is a block diagram of the operation of the locator receiver toprovide path loss slope data.

FIG. 7 is another exemplary application of the location system accordingto the present invention.

FIG. 8 is a schematic drawing illustrating the operation of theavalanche detector using three separate paths for locating an avalanchevictim used in accordance with the present invention.

DETAILED DESCRIPTION

The present invention provides a system and method that enables swiftand accurate location of a RF signal source such as emitted by adistress beacon. The present invention advantageously uses path lossslope readings in order to eventually locate the RF signal source thatis transmitted by the distress beacon. The present invention enables auser to acquire data with a handheld device and determine direction anddistance of a RF signal source. The direction is determined based uponsignal strength and the distance reading may be determined based uponpower level changes that occur over the distance traveled, defined aspower path loss slope.

Referring now to FIG. 1, a symbolic exemplary overview of a rescuedirectional locating system according to the present invention is shown.A RF transmitting beacon 120 floats on a body of water or is attached orheld above the water by a person requiring location and rescue depictinga search and rescue situation. However, the present invention may beused in various other applications such as land based rescue missionsand law enforcement applications, i.e. stolen vehicle recovery orfugitive apprehension. The beacon 120 preferably is attached to a personor object above the water surface and emits continuous RF signals 125 ofa predetermined frequency. A RF signal locator 100 on vessel 10 receivesthe RF signal 125 and provides the user with way point readings toassist in the location of the beacon 120.

FIG. 2 shows the face of a locator, RF signal locator 100 according tothe present invention. Antennas 101 a–101 d extend from the base ofsignal locator 100 in order to receive RF signals upon activation by theuser. FIG. 3 shows a graphical interface and control buttons associatedwith the signal locator 100. A power control button 106 activates thesignal locator 100 for operation. Before initiating a search, the usersets the search frequency by using a channel frequency selector 104. Thereceiver may be set at any desired search frequency, although a numberof the search and rescue missions involve locating beacons that transmitat 121.5 MHz. During operation a user may initiate a data acquisition byusing an electrical switch represented as a search trigger 102.Although, trigger 102 is shown as a control switch button, the triggermay also be activated through the use of an actual trigger, not shown,on the underside of the signal locator 100. Another contemplatedembodiment includes the signal locator 100 without any triggeringmechanism, wherein the signal locator 100 upon activation continuouslymeasures power changes in order to determine the path loss slope. Aprocessor, not shown, within the receiver provides distance estimationsbased upon the path loss slopes.

A graphical reading display (GRD) 110 provides a display of the realtime data and output data processed during the search. A RF signalstrength display 116 a shows the signal strength reading numerically andgraphically. A user pivots or rotates in a 360 degree direction whilepointing the signal locator 100 outwardly toward different compassheadings in order to initially locate the direction of the RF signalsource. The RF signal strength display 116 a displays the real timepower levels, wherein the power level readings assist in determining thedirection of the signal source. Above the RF signal strength 116 a,compass 116 b displays the direction that the signal locator 100 ispointing and changes accordingly upon movement. Below the signalstrength display 116 a, a search data display (SDD) 114 provides theuser with specific data regarding the different search modes and theassociated weighting of each mode.

The signal locator 100 includes three search modes: power slopecalculation, triangular vectors and data mapping. Each search mode isalways active and uses global positioning system (GPS) data, directiondata and power level data to associate the resulting way points for eachmode with an associated weight, i.e. confidence factor. The mode that isweighted the heaviest is displayed on the recommended mode way pointsection of the display using a standard GPS reading protocol. The SDD114 displays the GPS reading for each search mode below the recommendedmode way point and provides the weighting for each reading. The factorsfor processing which way point to use of the different modes are thedistance traveled toward, away or perpendicular to the RF beacon signaland whether a directional antenna is being used.

Below the SDD 114, a way point display (WPD) 112 provides the user withspecific compass direction and distance information. The compassdirection and distance information gives the user the estimated distanceand direction of the RF signal beacon source. The distance and directioninformation may change as more data is acquired and processed, andconsequently more accurate readings are produced as the user approachesthe RF signal source.

Referring now to FIG. 4A, a graphical display of RF signal power v.distance is shown. Distance is measured between the RF beacon signalsource and the locator, RF receiver. The graph of FIG. 4A shows that asdistance increases, the slope associated with the path loss curvedecreases to substantially zero. When a larger distance separates thesignal locator 100 and the RF signal source, the signal locator 100displays a large distance number for the way point 112. Under mostcircumstances the accuracy of the way point reading at longer distancesis not critical. The user simply knows at longer distances, one mustsimply traverse a substantial distance in order to locate the beacon. Asthe user continues the search toward the RF signal source and obtainsmore data, the receiver will read a greater slope change andappropriately provide the user with a smaller and more accurate waypoint reading closer to the distress signal. The present inventiontherefore allows the user to locate the RF signal source based upon theslope characteristics of the path loss curve. Referring to FIG. 4B,slope readings A–F along the path loss curve are depicted. As thedistance decreases, the slope readings increase A–F. Accordingly, a userreceiving readings at two miles or greater clearly understands togenerally proceed in the appropriate direction and that the RF signalsource is a large distance away from the signal locator 100. Having agreater certainty that the RF signal source is a substantial distancefrom the receiver, the user may move more swiftly without fear of overshooting the RF signal source. If the user is performing a water searchand rescue, then the user does not need to fear possibly running intothe RF signal source or the person in distress when receiving way pointreadings that represent longer distances. The distance readings based onthe power slope enable users to more quickly pinpoint the RF signalsource and more effectively perform a search and rescue.

FIG. 5A shows a flow chart describing the preferred method according tothe present invention. A user first initiates the search mode on thesignal locator 100, step 200. The user then maneuvers the signal locator100, step 210, in order to pick up a directional indication, step 215.The user begins to advance in the direction as indicated, step 220.Next, the user manually engages the search trigger 102 (FIG. 3) tosearch for a way point reading, step 225, and the locator 100 providesthe way point reading, step 230. The user continues in the direction ofthe way point reading, step 235, and manually triggers a subsequentsearch for a more precise way point reading, step 240. The usercontinues to advance in the direction of the way point/target, step 245,and repeats subsequent searches using trigger 102 until the RF signalsource is found, step 250.

FIG. 5B shows an alternative method according to the present invention.The user initiates a search, step 300. The user then maneuvers thesignal locator 100, step 310, in order to pick up a directionalindication, step 320. A processor in the signal locator automatically ispreprogrammed to provide way points based on different variables such assignal strength and location. Next, the user begins to advance in thedirection as indicated, step 330, while advancing the user receivescontinuous way point readings where the distance component is based onpath loss slope 340. This exemplary method allows the user tocontinuously advance toward the way point/target, step 350, until thetarget is found, step 360. Both the methods of FIGS. 5A and 5B providethe user with increasingly accurate way point readings as the userprogresses toward the RF signal source. Both methods use the path lossslope to quickly and efficiently located the signal source and thussubstantially minimize search time.

Referring now to FIG. 6, the direction distance finding system containedinside the receiver is shown in the block diagram. Beam directionalantennas 602 are connected to a calibrated frequency modulation (FM)receiver 604 that receives the RF signal and determines the RF signal'sstrength. The receiver 604 filters any noise associated with the RFsignal. The RF signal received from the beacon, which is a FM signal, isthen sent to a signal processing unit 606. The signal processing unit606 also receives data from a GPS receiver 610 and a compass 612. Abattery 620, connected to the signal processing unit, provides power tothe system. The signal processing unit 606 provides real-time data tothe real-time compass, GPS and signal strength displays 614 for displayon a readout display 625. The signal processing unit 606 also sends datato a data processor 608 a, where the data processor 608 a outputspredicted distance, direction and GPS coordinates based on the slope,triangulation or data mapping modes and the direction of the strongestsignal strength where an associated weight for each mode 618 shows onthe readout display 625. The data processor 608 a functions based uponinstructions from a memory unit 608 which also stores data received fromthe data processor 608 a. Based on the information received by thesignal processing unit 606, when the user activates a switch such as atrigger, the signal processing unit 606 will provide the new waypointreadings in the embodiment that includes a trigger for use by the user.Sensitivity down to −113 decibels milliamps is typical for the handheldversion. By using the signal processing unit 606 and the memory 608, thereceiver can provide predicted distance readings based on relativesignal strength as the user approaches the beacon.

Referring now to FIG. 7, another exemplary application of the presentinvention is shown. A monopole antenna 450 installed on a vehicle 440receives RF signals 425 emitted by a source beacon 420. A user in thevehicle 440 initiates a search for the beacon 420 by traveling over acertain area. A signal locator display, not shown, provides informationto the user regarding the reception received by the antenna 450. FIG. 7shows two exemplary paths that may be traversed by the vehicle 440 inorder to locate the beacon 420. Based upon the operator of the signallocator and the route available to the user, either path #1 or path #2may be traversed in order to locate the beacon 420. Regardless of theroute endeavored by the user, the signal locator consistently enablesthe user to locate beacon 420. Different resultant paths may betraversed due to the terrain, buildings and atmospheric conditions, allof which may affect the received signal. The signal locator obtainsinitial signal strength and displays a waypoint based upon subsequentstrength readings of the received RF signal over a certain area. Thesignal locator continuously receives RF signals and generates subsequentway point readings based on the received RF signal. The subsequent waypoint readings guide the user to the beacon 420 and allow the userflexibility in traversing toward the beacon 420 based upon terrain andenvironmental conditions.

The present invention is capable of providing direction and distanceestimates to one or more avalanche victims each having an avalanchebeacon for transmitting emergency distressed signals from the victim inthe event the victim is covered by an avalanche. The principles ofoperation of the present invention discussed above are also applicablefor use with avalanche beacons which are, typically, RF transmitters,many of which operate at 457 kHz frequency. The present invention tracksthe timing of each of the victim's transmissions to obtain data forlocating multiple victims.

The present invention also provides a system and method for locating theRF source if the transmitter emits a dipole flux pattern (magnetic fieldpattern). The present invention enables a searcher to locate the sourceof this field as emitted by a distress beacon (e.g. avalanche beacon 457kHz amplitude modulated) during a search and rescue operation.

The present invention advantageously not only provides directional dataas to the direction of the RF field source, but also provides anestimated distance between a searcher signal receiver and victim'stransmitter field source using path loss slope and/or triangulation(geometric calculations when searching for avalanche victims). Areceiver according to the present invention advantageously providesdirection and distance estimates based upon field signal strength, orfield strength changes, in a certain direction with regard to the fluxlines and/or over a certain distance.

In one exemplary embodiment of the present invention, a searcher using areceiver obtains the estimated direction and distance of the RF magneticfield source, i.e., the distress beacon.

The direction may be ascertained based upon field strength readingstaken by the receiver where the strongest field strength reading isoriented parallel to the induction line from the transmitter. Afterobtaining the direction of the induction lines, the searcher moves acertain distance (e.g., eight feet) in any direction while receivingmore signal strength data and flux line direction information enablingthe algorithm to analyze the data and direct the searcher in the bestdirection to obtain optimum data or towards the location of the source.

The distance would be calculated using the path loss slope mode (highrate of change close to the transmitter and a decreasing slope thefurther away from the transmitter one is). The signal strength may alsobe used to determine distance if the radiated power of the transmitteris known, which is commonly the case with avalanche beacons.

The user may then proceed in the indicated direction where additionaldata and processing results in increased accuracy of the location of theRF source.

The source location of the RF magnetic field is determined based on thealgorithm's calculations using one or more of the following:

-   -   a. the direction of the flux lines;    -   b. the direction of the flux lines with respect to each other        and taking into consideration the characteristics of the fields,        including near and far fields;    -   c. the field strength in the said flux field direction and 180        degree in the other direction;    -   d. the flux line path (curve) taken with regard to the offset        (change in direction) from a straight tangential line referenced        from the original direction of the flux lines;    -   e. the field strength rate of increased (based on path loss        slope and flux line direction and the characteristics of the        field) while obtaining more data or traversing towards the        source;    -   f. the maximum signal strength may be used to estimate distance        when the radiated power of the transmitter is known; and    -   g. the transmission duration and timing.

In general, yielding to the complexity of the field characteristics, asthe distance between the receiver and beacon decreases, the path lossslope dramatically increases.

Referring now to FIG. 8, three examples of different avalanche beaconsearch paths are shown that use direction and distance finding. Theassumption is that a victim is located under an avalanche at the letter“E.” Dipole radiation from the victim's transmitter is shown aselliptical lines from “E.” A first path using the present invention witha receiver to locate the victim “E's” transmitter could begin at point“A” to point “B.” From point “A” to point “B,” received flux informationis processed to display the direction and distance to the transmitter“E.” The path then from “B” to “E” increases the rate of change ofsignal strength as the distance decreases. Using geometry, the knowncharacteristics of a dipole flux pattern which is shown in FIG. 8, pathloss slope or signal strength, and compass direction, the algorithms inthe present invention calculate the estimated location of the beacon atposition “E.”

Using a second path, the rescuer at “F” traverses to point “G.” Fluxinformation is processed to display the direction and distance then from“G” to “E.”

In a third separate path to locate the victim at “E” from a rescuerlocated at point “C,” from “C” to “D” flux information is processed thatwill provide in the rescuer, the direction and distance to “E.”

Thus, using three different examples of different paths in the vicinityof the avalanche victim located at “E” using the present invention,rescuers starting at point “A,” point “F” or point “C” can determine notonly the direction of the victim's transmitter at “E” but also calculatethe approximate distance. As shown in FIG. 8, there is peak power in thedirection of the flux lines. The difference between the two directions(tangents from A and B) while traveling along them provides the data tothe processor necessary to indicate the general location of thetransmitter. Additional data taken when during the search improves theaccuracy.

The path loss slope is the x-y graph of the beacon signal power strengthas a function of distance and the searchers location in the field.

The present invention advantageously exploits a 457 kHz amplitudemodulated (AM) dipole flux pattern that would be typical of an avalanchebeacon.

A graphical display may provide the user with an initial way pointreading that includes directional and distance data associated with themagnetic field source.

The estimated location of the distress signal (RF field source) could berelative distance in a compass direction or with data processing and atrue north declination offset could be a GPS coordinate on a detailedcolor map.

The directional and distance data is based upon the received RF signals.A processor within the locator receives, measures and stores RF peaksignal strength of transmissions emitted by the RF signal source throughthe use of algorithms. The locator advantageously provides continuoussubsequent way point readings for the user, where the subsequent waypoint readings include directional and distance data associated with theRF signal source. The distance data within the subsequent way pointreadings may be based upon a path loss slope of the received RF signals.

The instant invention has been shown and described herein in what isconsidered to be the most practical and preferred embodiment. It isrecognized, however, that departures may be made therefrom within thescope of the invention and that obvious modifications will occur to aperson skilled in the art.

1. A method for locating a RF signal source from an avalanche distressbeacon from a victim buried in an avalanche using a signal locatorcomprising: a. initiating a search using the signal locator; b.maneuvering the signal locator toward a plurality of compass directionsin order to process RF signal strength data of the avalanche beacon inthe plurality of compass directions; c. moving a small distance andagain maneuvering the signal locator toward a plurality of compassdirections in order to process RF signal strength data of the avalanchebeacon in the plurality of compass directions; d. obtaining adirectional and distance output (waypoint) of the RF signal source ofthe avalanche beacon based upon the output of algorithms; e. advancingthe signal locator towards the initial way point reading. f. initiatinga subsequent way point reading, based on subsequent directional readingsand subsequent distance readings, where the subsequent distance readingsare based upon the rate of change of the RF signal from the avalanchebeacon as received by the signal locator; g. continuing to advance thesignal locator; and h. repeating steps f–g until the RF signal sourcefrom the avalanche beacon is located.
 2. The method for locating thesource of a RF signal according to claim 1 further comprising the stepof: a. triggering each subsequent way point reading.
 3. The methodaccording to claim 1, wherein said way point reading is displayed usingGPS coordinates.
 4. The method according to claim 1, further comprisingthe step of: a. designating a RF signal frequency.
 5. The method forlocating the source of a RF signal according to claim 1, furtherincluding the step of providing at least one search mode.
 6. The methodfor locating the source of a RF signal according to claim 5, wherein theat least one search mode includes a power slope mode, a triangulation(geometrical calculation) mode and a data mapping mode.
 7. The methodfor locating the source of a RF signal according to claim 1, furtherincluding the step of providing a visual display for the signal locator.8. The method for locating the source of a RF signal according to claim7, further including the steps of: a. incorporating a signal strengthreading on the visual display; b. displaying the initial way pointreading on the visual display; and c. displaying a recommended searchmode on the visual display.
 9. The method for locating the source of aRF signal according to claim 7, further including the step of providinga GPS coordinate for each search mode.
 10. The method for locating thesource of a RF signal according to claim 1, wherein said signal locatoris at least one of a handheld signal locator and a mobile signallocator.